Managing light system energy use

ABSTRACT

A first lighting assembly receives a lighting profile that instructs the first lighting assembly to operate according to the lighting profile over a first period of time. The received lighting profile is implemented, including causing a light of the first lighting assembly to illuminate at a first intensity. An input acquired in proximity to the first lighting assembly and indicating activity in a region proximate the first lighting assembly is received. The received lighting profile is then deviated from, in response to the received input, by increasing the intensity of the light to illuminate at a second intensity for a predetermined period of time. A message is transmitted for receipt by the control center, the message including an indication of the increased light intensity and an identifier associated with the first lighting assembly.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. Pat. No. 13/229,542, filed onSep. 9, 2011, which claims the benefit of U.S. Provisional ApplicationNo. 61/381,121, filed Sep. 9, 2010. The content of the foregoingapplications is hereby incorporated by reference in their entirety.

TECHNICAL FIELD

This disclosure relates to managing energy use in a system of lights.

BACKGROUND

Costs associated with energy use by streetlights or parking lot lightscan be a significant portion of a city budget. For example, in somecases costs associated with powering such lights can represent up to 10%of a city's operating budget. One way of minimizing energy use in streetlights is to equip the lights with an ambient light sensor that causeseach light to individually be fully powered on each evening when thesensed ambient light drops to a particular level. Similarly, the sensormay sense increasing ambient light in the morning as the sun rises, andmay cause the light to be completely powered off at that time.

SUMMARY

In a first general aspect, a computer-implemented method of managingenergy use in a system of lights includes receiving, at a communicationsreceiver of a first lighting assembly, a lighting profile that instructsthe first lighting assembly to operate according to the lighting profileover a first period of time, where the lighting profile is receivedwirelessly by the communications receiver from a control center remotefrom the first lighting assembly. The control center additionallyprovides lighting profiles to a plurality of other lighting assemblies.The method also includes implementing, at the first lighting assembly,the received lighting profile, including causing a light of the firstlighting assembly to illuminate at a first intensity. The method furtherincludes receiving, at a sensing module of the first lighting assembly,an input acquired in proximity to the first lighting assembly, the inputindicating activity in a region proximate the first lighting assembly.The method further includes deviating from the received lighting profileby increasing the intensity of the light of the first lighting assembly,in response to the received input acquired in proximity to the firstlighting assembly, by causing the light of the first lighting assemblyto illuminate at a second intensity for a predetermined period of time,the second intensity greater than the first intensity. The methodfurther includes wirelessly transmitting a message via a communicationstransmitter of the first lighting assembly for receipt by the controlcenter, the message comprising an indication of the increased lightintensity and an identifier associated with the first lighting assembly.

Implementations may include one or more of the following. The input mayinclude a radio frequency signal indicative of mobile electronic deviceused within the region proximate the first lighting assembly, or aBluetooth signal. The input may include detected motion within theregion proximate the first lighting assembly. The input may include asound, for example, such as a sound associated with a motorized vehicle.The sensing module may compare the received sound to one or more storedrepresentations of sounds, may identify a similarity between thereceived sound and one of the one or more stored representations ofsounds, and the second intensity may be based on the identifiedsimilarity. The input may include a light signal. The method mayadditionally include initiating a timer when the light intensity of thelight of the first lighting assembly is increased, the timer to countfor the predetermined period of time, and reverting to the receivedlighting profile in response to the timer counting for the predeterminedperiod of time. The predetermined period of time is associated with thereceived input, and a first predetermined period of time associated witha first input may differ from a second predetermined period of timeassociated with a second input. Responsive to receiving the input, acontrol module of the first lighting assembly may increment a counterand delay the deviating from the received lighting profile until thecounter reaches a profile deviation threshold value. Incrementing thecounter may include incrementing the counter by a count value, where thecount value may be determined based on the received input, and wheredifferent types of received input may cause the counter to beincremented by different count values. The method may also includereceiving, at the communications receiver of the first lightingassembly, a communication from a second lighting assembly, and varyinglight intensity of the light of the first lighting assembly based on thereceived communication from the second lighting assembly. The messagemay include an indication of energy usage by the first lightingassembly. The message may include a request that the control centerinstruct lighting assemblies in a vicinity of the first lightingassembly to adjust their light intensities. The method may also includewirelessly transmitting a second message via the communicationstransmitter of the first lighting assembly for receipt by the otherlighting assemblies, the second message including an instruction to theother lighting assemblies to adjust their light intensities. The messagemay also include receiving, at the communications receiver of the firstlighting assembly, a second lighting profile, and implementing, at thefirst lighting assembly, the second lighting profile rather than thefirst lighting profile, the second lighting profile received wirelesslyby the communications receiver from the control center. The method mayalso include receiving, with the lighting profile, a security question,the lighting profile and the security question included in a messagefrom the control center, and wherein accessing the lighting profile isdependent on the first lighting assembly providing a correct answer tothe security question.

In a second general aspect, a lighting assembly includes a light, and acommunications receiver configured to receive a lighting profile thatinstructs the lighting assembly to operate according to the lightingprofile over a first period of time, the lighting profile receivedwirelessly by the communications receiver from a control center remotefrom the lighting assembly, wherein the control center additionallyprovides lighting profiles to a plurality of other lighting assemblies.The lighting assembly also includes a light control module configured toimplement the received lighting profile, including causing the light toilluminate at a first intensity. The lighting assembly further includesa sensor module configured to receive an input acquired in proximity tothe lighting assembly, the input indicating activity in a regionproximate the lighting assembly. The light control module isadditionally configured to deviate from the received lighting profile byincreasing the intensity of the light, in response to the received inputacquired in proximity to the lighting assembly, by causing the light toilluminate at a second intensity for a predetermined period of time, thesecond intensity greater than the first intensity. The lighting assemblyadditionally includes a communications transmitter configured towirelessly transmit a message, for receipt by the control center, themessage comprising an indication of the increased light intensity and anidentifier associated with the lighting assembly.

Advantages that may be provided by the systems, devices, and methodsdescribed herein can include one or more of the following: reduced powerconsumption, energy savings, cost savings, reduced light pollution,coordinated lighting functionality, responsive lighting behavior,on-demand lighting provision, secure lighting command communicationpathways, increased public safety, and adaptive lighting behavior.

DESCRIPTION OF DRAWINGS

FIG. 1 shows a schematic of a street light management system inaccordance with the present disclosure.

FIGS. 2A, 2B, and 2C show different examples of lighting profiles inaccordance with the present disclosure.

FIGS. 3A to 3F illustrate different example operation schemes for thestreet light management system.

FIG. 4 shows an example lighting profile in various impromptu situationsin accordance with the present disclosure.

FIG. 5 illustrates an example system diagram of a light assembly and acentral controller in accordance with the present disclosure.

FIG. 6 illustrates an example network system for connecting the lightassembly to the central controller in the street light management systemin accordance with the present disclosure.

FIG. 7 shows an example method that may be performed by a lightingassembly in accordance with the present disclosure.

FIG. 8 is a schematic diagram of a generic electronic system 800

Like reference symbols in the various drawings indicate like elements.

DETAILED DESCRIPTION

Described herein are systems, devices, and techniques that can be usedto reduce energy consumption in street lighting systems or parking lotlighting systems. In various implementations, a combination of remotecontrol of individual or groups of streetlights by a control station maybe combined with local detection of activity at or near a particularlighting assembly may be used to reduce the amount of energy used by aparticular streetlight or group of streetlights. For example, thecontrol station or control center may provide or command a particularlighting profile or set of illumination instructions to a lightingassembly. The lighting profile may be designed to minimize or reduceenergy use by the light versus a traditional schedule of turning thelight fully on at dusk, leaving the light fully on all night, andturning the light off in the morning. Additionally, the lightingassembly may deviate from the received lighting profile by alteringillumination characteristics of the light based on one or more inputssensed at or near the lighting assembly. Examples of sensed inputs thatmay cause the lighting assembly to deviate from the lighting profile caninclude sensed motion, sensed audio input (e.g., sounds), sensedcommunication signals (e.g., radio frequency (RF) signals of variouskinds), sensed particulates in the air (e.g., smoke, natural gas),dedicated input signals directed to the assembly (e.g., a laser beam),and others. In various implementations, the lighting assembly may alteror change light output intensity in correspondence to the detectedcondition. For example, in some cases the assembly may increase lightintensity; in some cases the assembly may decrease light intensity; insome cases, the assembly may alter intensity (increase or decrease)according to a predetermined pattern.

For example, street light systems may be configured to adapt toenvironment changes as well as human activities. In general, the systemmay operate to reduce the amount of power consumed by the lightingassemblies to reduce the amount of energy used. This may includeproviding less light than has been traditionally provided during certainperiods of time, for example, as by powering the lights at a reducedlevel or leaving the lights off for periods of time where theytraditionally would have been fully powered. They system neverthelessprovides adequate lighting by reacting to activity sensed within aproximity of a particular lighting assembly, so that pedestrians,motorists, and other “users” of lighting systems are adequately served.In some cases, the street light assemblies may intelligently respond toemergencies, accidents, and events. In some cases, the street lightassemblies may be optimally preprogrammed to minimize energy consumptionin a wide area wherein a number of light assemblies are interconnectedvia a secure network system. In various implementations, securityprovisions are included with communications passed between components ofthe street light system to prevent unauthorized access. The system canbe configured to store records of energy use, changes in environmentalfactors, human activities, and statuses of components of the systems forestablishing a reference library for generating an optimal controllighting profile.

Advantages that may be provided by the systems, devices, and methodsdescribed herein can include one or more of the following: reduced powerconsumption, energy savings, cost savings, reduced light pollution,coordinated lighting functionality, responsive lighting behavior,on-demand lighting provision, secure lighting command communicationpathways, increased public safety, and adaptive lighting behavior.

FIG. 1 shows a schematic of a street light management system 100 inaccordance with the present disclosure. The street light managementsystem 100 includes a generic grid representation 110 of streets, suchas streets in a city, an array of street light assemblies 120 a, 120 b,120 c, . . . , 120 i distributed in the grid 110, a network 130 and acentral controller 140. The street light assemblies 120 are individuallycommunicably connected to the central controller 140 via the network130, as represented by communication paths 125 (for simplicity,individual communication paths are shown but are not individuallylabeled). The communication paths 125 may represent wirelesscommunication paths in some implementations. In other implementations,some or all of the communications paths 125 may represent wired paths.Although in this implementation, the street grid 110 is shown to havethree avenues by three streets, the street grid 110 may represent anystreet layout in a selected area. For example, one central controller140 may control the street lights for an entire town or city in someexamples. In some examples, a city may include two or more centralcontrollers 140. Similarly, the array of street light assemblies mayinclude a number of actual light assemblies 120 suited for the streetgrid 110, in accordance with legal and/or safety regulations.

In some examples, communications between the street light assemblies 120and the central controller 140 may occur over a secure network, or mayinclude security provisions associated with each communication as willbe described below. The network 130 may directly or indirectlyconnect/integrate with the central controller 140. During operation, thestreet light assemblies 120 may first receive a lighting profile thatcontains instructions for operation from the central controller 140. Thestreet light assemblies 120 may then execute the received lightingprofile. The lighting profile can take any number of forms, and canconvey any number to instructions. In some examples, the profile mayinclude a power function over time. In some examples, the profile mayinclude a schedule of light intensities over time. In some examples, theprofile may include durations over which certain light intensities canbe implemented by the lighting assemblies. In some examples, the profilecan be tailored for a particular season or time of the year, based onfactors associated with the season or time or the year (e.g., hours ofdarkness, moon phases, and the like). In some cases, the profile can betailored to present or expected weather conditions. The lighting profilecan be defined to optimally save energy. For example, the lightingprofile may be defined to produce an illumination just bright enough forperception of the human eyes in combination with ambient light, such asday light and moon light.

In some implementations, the lighting profile includes an onset timerelating to the expected time of sunset, or to account for annual daytime variation, or latitude variation. For example, the lighting profilemay be generated using historic data of ambient light to predict thelight change gradient during sunset and sunrise so that the total energyconsumption can be minimized. In various implementations, the streetlight assemblies 120 may include sodium vapor lights, light emittingdiodes, incandescent light, fluorescent light, neon light, and/or othertypes of luminaire suitable for street illumination. The street lightassemblies 120 may be beacon lights, roadway lights, parking lot lightsor parking ramp lights, under various implementations.

The street light assemblies 120 may include a sensing module that canreceive input indicative of activity in proximity to the street lightassemblies 120. For example, the street light assembly 120 may includean audio sensor (e.g., a microphone) for receiving audio input, such asthe sound of made by people, animals, machinery, or the like, or a siren(e.g., police, fire dept., ambulance), a gunshot, a crash, breakingglass or other material, and/or a scream. Based on the received input,the street light assemblies 120 may deviate from the first receivedlighting profile, for example, by increasing the light intensity (or bydecreasing intensity in some cases). This can permit, in someimplementations, the street light assemblies 120 to be operating at theleast acceptable energy emitting conditions until surrounding activitieswarrant a situation for higher illumination or power consumption.

This interactive operation may be carried out locally at the lightassemblies 120 as well as connectedly via the network 130 at the centralcontroller 140. Either the light assemblies 120 or the centralcontroller 140 may have the authority to override the first issuedlighting profile in some implementations. For example, the centralcontroller 140 may communicate a second lighting profile that overridesthe first lighting profile in some cases. In some examples, the system100 may be configured so that only one component may have the highestauthority for a final overriding command.

In various implementations, when a light assembly (e.g., assembly 120 a)deviates from a received lighting profile based on sensed activity, theassembly may transmit a message to the central controller 140. Themessage may include, for example, an identifier that identifies theassembly (e.g., assembly 120 a), and an indication of the deviation. Forexample, if the deviation includes an increase in light intensity, themessage may indicate the increase, either abstractly or by including anindication of the amount or degree of the increase. In some cases themessage may include an indication of the sensed input that preceded thedeviation. In some cases the message may include status informationregarding the lighting assembly, or status information concerning one ormore other lighting assemblies.

In various implementations, network 130 may be a local or wide areanetwork, the Internet, a microwave network, a wireless or wired network,or various combinations of the foregoing. Portions (or all) of network130 may be proprietary in some cases. The channels 125 may represent acommercial network channel, an operator microwave channel, a radiofrequency channel, or other types of secure channels (or not secured insome implementations) that connect each light assembly to the network130. In some cases, light assemblies may communicate directly with oneanother over network 130 or otherwise. For example, assembly 120 a maysend a message to assembly 120 b (and any appropriate number of otherassemblies) in some implementations, such as a message to increase lightintensity at assembly 120 b based on detected activity by assembly 120a.

FIGS. 2A and 2B show different example lighting profiles 205 and 210 forcontrolling the street light management system in accordance with thepresent disclosure. In FIG. 2A, the example lighting profile 205represents an example summer sunny day profile predetermined accordingto a total lighting profile. In the implementation illustrated in FIG.2A, the horizontal axis represents the daily hour, from midnight tomidnight in this example. In other examples, profiles can coverdifferent periods of time (e.g., 6 hours, 8 hours, 10 hours, 12 hours,48 hours, 72 hours, one week, one month, or the like). The vertical axisrepresents light intensity percentage. The street light profile that issent to the street light assemblies 120 may be defined in various ways.In some examples, it may be defined based on a total light profiledesired and an ambient light profile. In some examples, the profile maybe a simpler profile than illustrated in FIGS. 2A and 2B, and may simplydirect the lighting assembly to illuminate at one or more particularintensities over a particular time period, such as a schedule of perhapsdifferent light intensities at different times or durations within thetime period (e.g., on at 40% for 1 hour, then on at 80% for the next 4hours, then on at 25% for the next 4 hours, then off).

Referring again to FIG. 2A, the total light profile may considered toprovide sufficient lighting for a particular area, and in someimplementations may be considered to comprise a sum of light provided bya streetlight and by ambient lighting conditions. As such, street lightillumination may be required only when ambient light (e.g., lightprovided by sun or moon, or other lighting sources such as buildinglights, ball-field lights, etc.) is insufficient. As the ambient lightprofile varies according to seasonal changes as well as geographicalfactors, the light intensity provided by the street light may be varied.The street light lighting profile can therefore be predetermined tosupplement the available ambient light to achieve a total light profilethat maximizes energy savings.

As illustrated in FIG. 2A, in a sunny summer day, ambient light may beample from 6 am to 8 pm. As the sunlight increases in the morning anddecreases in the evening, illumination of the street light may be variedaccordingly. The street light profile may increase energy output earlyat 6 in the morning as daily activity begins. The power output thendecreases to zero from 6 am to 8 am as the sun rises. As the sun startssetting at 6 pm, the power output for street lights increase to offsetthe diminished ambient light, and provide sufficient lighting during atime when activity where lighting is desirable is still expected to beprevalent. As the human activity begins to decrease later in the evening(e.g., after 10 pm), the street light may be dimmed (gradually, forexample), to a lower intensity for saving energy. The cycle can repeatwith seasonal variations recorded for the ambient light profile.

The predetermined street light profile 205, or a portion of it (e.g.,the street light profile portion) can be sent from the centralcontroller 140 to the street light assemblies 120 via the network 130over a communication path 125, as illustrated in FIG. 1. Such a profilecan, in some implementations, effectively reduce energy consumptionduring periods where full intensity lighting is not needed. In addition,such lighting control profile may also be predetermined in weathervariation scenarios as shown in FIG. 2B.

FIG. 2B shows an example lighting profile 210 for a summer rainy day.Historical data representing the ambient light profile of a summer rainyday can first be gathered and approximated, and this may occur at thecentral controller 140, for example. The horizontal axis represents thedaily hour, from midnight to midnight. The vertical axis representslight intensity percentage. The street light profile that is sent to thestreet light assemblies 120 may be defined based on the total lightprofile required and the ambient light profile. In this example, becauseof cloudy situation in a rainy day, sunlight has been significantlydelayed and reduced, as shown in the ambient light profile. The outputfor the street light is then boosted to compensate the total lightprofile.

In some implementations, the street light profile may be defined withoutassociation with expected or actual ambient light characteristics. Forexample, FIG. 2C shows a profile defined with respect to lightintensities over certain times of a day. As shown, in FIG. 2C, theprofile may instruct the lighting assembly to illuminate at 30%intensity from 8:00 PM to 9:30 PM, and then to step or ramp up to 80%intensity at 9:30 PM and remain at 80% intensity until 1:00 AM, and thento step or ramp down to 25% intensity at 1:00 Am and remain at thatlevel until 5:00 AM, and finally to ramp down to 0% (off) during thetime from 5:00 AM to 6:00 AM. Other example profiles are possible. As analternative to times of the day, the profile may indicate a start time(or the start time may be the time received by the assembly), andinclude durations for each lighting level. A simple profile may call forillumination at 60% from 9:00 PM to 5:00 AM (or for a duration of 8hours from a given start time, e.g.). These alternatives may simplifythe lighting profile definition and may not include historical data insome examples.

The illustrated street light profiles as shown in FIGS. 2A, 2B, and 2Care examples of various profiles that can be provided from the centralcontroller 140 to the lighting assemblies. In various implementations,different lighting assemblies may receive different profiles, based onlocation, expected activity, anticipated events, population density, orother factors. The profiles can consider various regular and constantfactors in some cases, such as ambient light variations and publicactivities. Although the street lighting profile can be remotelycommanded by the central controller, during normal operation, asdescribed in FIG. 1, sensing devices in the street light assemblies mayalter the final behavior for adapting activity requirements. This isfurther discussed in FIGS. 3A to 3F.

FIGS. 3A to 3F illustrate different example operation schemes for thestreet light management system. As shown in FIG. 3A, the street lightassembly 310 may be equipped with a motion sensor (not shown) to detectthe presence of pedestrians 331 (e.g., pedestrians walking on asidewalk). The motion sensor can be a passive infrared sensor, anultrasonic sensor, a microwave sensor, and/or a tomographic detector invarious implementations. The motion sensor may detect the presence of anapproaching person. In some cases, the assembly may deviate from thelighting profile and increase a light intensity of the light based onthe detected input (motion). The street light assembly may react to thesensed signal independent of the central controller, and may temporarilyincrease the light intensity. For example, the light intensity may beincreased from 30% to 80% when someone's presence is detected. Theincrease may be temporary, such as for a predetermined period of time,and thereafter the assembly may revert to the intensity specified by thelighting profile. For example, the light assembly may increase to 80%intensity for two minutes, 5 minutes, or any appropriate time (perhapsbased on the type of detected input), and may return to the original 30%intensity thereafter. The light assembly may also stay at the 80%intensity until no presence signal is further detected in variousimplementations.

In some implementations, the motion sensor may be a passive infraredsensor that detects body heat. The motion sensor may detect up to 15 to25 meters, or any other suitable range for one street light. In someimplementations, the motion sensor may be an ultrasonic sensor thatsends out pulses of ultrasonic waves and measures the reflection off amoving object. The reflection measurement may use Doppler Effect todetermine if there is relative motion between the object and the sensor.In some implementations, the motion sensor may be a microwave sensor,which sends out microwave pulses and measures the reflection off amoving object. This reflection measurement may also use Doppler Effectto determine the relative velocity and may be used to measure at alarger range. In some implementations, the motion sensor may be atomographic detector that senses disturbances to radio waves as theradio waves travel through an area surrounded by mesh network nodes.

The array of street light assemblies 310 in an area may all beinteracting with the moving presence. For example, the intensityvariation of the light may vary as the location of the presence varies.Multiple street light assemblies 310 may communicate with each other inthe network to predict a next variation. In some cases, a particularstreet light can send a message instructing another light to vary itsintensity. If multiple presences are detected, corresponding lightassemblies may interact with the presences simultaneously. Multiplepresences may also further increase the reacting light intensity. Forexample, if two or more individuals are detected, the output intensitymay be correspondingly set to a higher intensity (e.g., 90% or 100%).

As described above, upon detecting activity and deviating from thelighting profile, the lighting assembly may transmit (e.g., wirelessly)a message to the control center 140 indicating the deviation. In variousimplementations, a message may be sent each time a deviation from aprofile is implemented, or deviations may be compiled at the assemblyand a summary message including more than one deviation, optionally withtime stamps associated with each, may be sent later (e.g., periodicallyeach hour, once per day, or the like).

In FIG. 3B, the street light assembly 310 may be equipped with a longrange motion sensor and/or a light sensor for detecting approachingvehicles. The long range motion sensor may be an ultrasonic sensor, amicrowave sensor, and/or a tomographic detector. The street lightassembly may react to the sensing signal by temporarily increasing thelight intensity. For example, the light intensity may be increased from30% to 80% when a vehicle's presence is detected and the light assemblywould stay at the 80% intensity for a period of time and return to theoriginal 30% afterwards. The light assembly may also stay at the 80%intensity until no presence signal is further detected.

In some implementations, the street light assembly 310 is equipped witha light sensor for detecting the headlight of an approaching vehicle.The light sensor may be a photo diode, an active pixel sensor, acharge-coupled device, or other types of photo detector. The photo diodeis capable of converting light into current or voltage. The photo diodemay be operating under photovoltaic mode, photoconductive mode, and/orother modes. The light sensor may be an image sensor such as thecharge-coupled device with optics to capture images at the scene. Animage processor may be available to process the captured image andinterpret the presence of an approaching vehicle.

In FIG. 3C, the street light assembly 310 may be equipped with an audiosensor, such as a microphone, to capture certain audio signals. Invarious implementations, the signals may be compared to stored signalsto determine whether a deviation from the lighting profile is warranted.Signatures may be stored for signals such as sirens of police patrolcars, fire trucks, or ambulances, gunshot sounds, crash sounds, criesfor help or assistance, explosions, and others. The microphone may beoperating under electromagnetic induction (dynamic microphone),capacitance change (condenser microphone), piezoelectric generation, orlight modulation to produce an electrical voltage signal from mechanicalvibration. This may enable the street light assembly 310 to detect soundpatterns and identify the pattern by comparison with references in adata library. If police siren is detected, for example, the street lightassembly may respond with a maximum output in the detected area toassist the police operation. In various implementations, the light maydirect all lights within a proximity (e.g., one or several blocks) ofthe light to alter their illumination levels. The assembly may send amessage to the central controller 140 as discussed above. In someimplementations, the light assembly 310 may relay to a GPS database thatdetects any police vehicles that pass nearby and react accordingly.

In FIG. 3D, the street light assembly 310 may be equipped with radiofrequency sensors for detecting the radio frequency activity. Forexample, radio frequency activity may be used as a proxy for humanpresence, as people often use mobile phones or other mobile electronicdevices while out and about. In some implementations, signal strengthmay be detected. This may enables the street light assembly 310 tomonitor the presence of carriers of electronic devices that emit radiofrequencies. The strength of the total radio frequency may indicate thesize of the active group so that the street light assembly 310 may reactaccordingly. For example, if a high strength radio frequency signal isdetected, the street light assembly 310 may accordingly increase lightintensity. Other street light assemblies in proximity may also be awareof the situation via the network and central controller and actsimilarly. Bluetooth signals or other electronic communications signalsmay also be detected.

In some examples, a user may transmit an electronic message for receiptby the light assembly, where the message requests additional light for aperiod of time. For example, an electronic device may be designed to“chirp” an electronic signal that is recognized by the lighting assemblyas a request for additional light, and the light may react by providingadditional light. In some cases, the request may be associated with aparticular electronic device or user, so that the user may be charged orbilled for the request. In some cases, the user may have a collection ofpaid-for or granted token requests, and when the light reacts byproviding additional light, one or more of the token requests may bededucted from the user's balance.

In FIG. 3E, the street light assembly 310 may be equipped with an audiosensor together with a data library including audio data of variousscenarios of interest. For example, the data library may includedifferent instances of the sound of glass shattering, gun shots, andhuman scream. The audio sensor may be a microphone, such as a microphoneworking under electromagnetic induction (dynamic microphone),capacitance change (condenser microphone), piezoelectric generation, orlight modulation to produce an electrical voltage signal from mechanicalvibration. The library of sounds may be stored in memory of the lightingassembly, for example.

In FIG. 3F, the street light assembly 310 may be receiving instructionsfrom a network that allows remote online users to vote for a change inthe lighting profile. This may be useful when a change of schedule ofpublic activity occurs, or other situation when other equipped sensorscannot appropriately adjust the light intensity according to the publicneeds.

The street light assembly 310 may be equipped with a combination of one,some, or all of the sensors described in FIGS. 3A to 3F, depending oninstallation preference or on an importance of the street light assembly310 location. The sensors enable the street light assembly 310 to detectactivity of its surroundings and accordingly deviate from the lightingprofile.

FIG. 4 shows an example lighting profile 400 in various impromptusituations in accordance with the present disclosure. The examplelighting profile 400 illustrates an actual lighting profile in whichlight intensity deviates from planned profiles. The selected time periodis from midnight to 4 am, as indicated in the horizontal axis inminutes. The vertical axis indicates the lighting energy outputpercentage from 0 to 100%. The planned lighting profile has been set at15% light intensity if no proximity activity is detected. As shown inFIG. 4, five incidents 410, 420, 430, 440 and 450 have occurred atrespectively 0030, 0050, 0120, 0210 and 0320 hours.

At the 0030 hour, movement of a pedestrian is detected by a motionsensor in the street light assembly, indicated by the incident 410. Thestreet light assembly accordingly increases the light intensity from 15%to 60% (as an example, other values are possible) for a period ofminutes. At 0050 hour, movement of a motor vehicle has been detected bya photo detector in the street light assembly, indicated by the incident420. The street light assembly accordingly increases the light intensityfrom 15% to 60%. In both these scenarios, the street light assembly mayincrease the light intensity for a period of time, measured by aninternal timer, and revert the light intensity back to 15% once the endof the time period is reached, and otherwise continue to follow theprofile thereafter.

At 0120 hour, siren of a police patrol car is detected by an audiosensor in the street light assembly, indicated by the incident 430. Thestreet light assembly increases the light intensity from 15% to 100% inthis example. At 0210 hour, a sound of gunshot is detected by amicrophone in the street light assembly, indicated by the incident 440.The street light assembly compares the detected sound with referencedata in a stored library of sounds to identify the type of sound, anddetermines it is a gunshot; then the street light assembly accordinglyincreases the light intensity from 15% to 100%. In both these scenarios,the street light assembly may increase the light intensity for apredetermined or indefinite period of time, for example until a releasesignal is sent from the central controller via network 130 to thelighting assembly. The central controller may receive the release signalfrom the police department, in some examples. In other examples, thepolice, fire, or utility companies may directly communicate with anindividual lighting assembly without going through the centralcontroller.

At 0320 hour, the radio frequency intensity is measured to be over athreshold value and this triggers the light assembly to change thelighting profile as indicated by the incident 450. The street lightassembly accordingly increases the light intensity from 15% to 100%.

In some examples, the lighting assembly may delay deviating from theprofile until a sufficient number of input activity events have beendetected. The assembly may include a counter that increments when anactivity is detected and compares the value to a threshold, and deviatesfrom the profile if the value meets or exceeds the threshold. The countvalue may vary depending on the type of input (e.g., a higher countvalue for a police siren than for a regular passing vehicle). Theassembly may monitor over a fixed or sliding window of time, forexample. The counter may decrement after periods of inactivity (i.e.,lack of detected activity) in some cases.

FIG. 5 illustrates an example system diagram of a light assembly 120 anda central controller 140 in the street light management system inaccordance with the present disclosure. The light assembly 120 may bethe same as the light assembly 120 in FIG. 1; and the central controller140 may be the same as the central controller 140 in FIG. 1. In thisimplementation, the light assembly 120 may include a sensor module 510,a communication module 520, a light control module 530, a light 540, apower source 560, a security module 550, and a reference library 570.

The sensor module 510 may include an audio sensor for detecting soundsin various frequency ranges, a light sensor for detecting the change ofambient light, a motion sensor for sensing proximity activities, acommunication signal sensor for detecting or receiving communicationsignals, and a power consumption sensor for measuring power consumptionin the light assembly 120. The power consumption sensor may measure therate of power use as well as the total amount of power consumption atthe light assembly. Other sensor types have been discussed in FIGS. 3Ato 3F. Other sensors that could be included in sensor module 510 couldbe particular sensors that sense for smoke, natural gas, chemicalsdispersed in the air, and the like.

An energy consumption calculator (not shown), may be included to monitorthe energy use in the street light assembly by measuring Amp-hour and/orWatt-hour readings. The lighting assembly 120 may transmit thismeasurement data to the central controller 140 via the communicationmodule 520 (e.g., over antenna 580). This information may be analyzed inthe central controller 140 and used to improve the energy savinglighting profile.

The communication module 520 may include a receiver and a transmitter.The receiver converts signals from a radio antenna 580 to a usable form.The receiver may receive electromagnetic waves at a certain frequencyand demodulate the signals into useable form. The transmitter can sendmessages, including the sensing data as well as other data forms to thecentral controller 140 over antenna 580 (or another antenna). Thecommunication module 520 may also include other devices that allow for asecure connection. The communication module 520 is connected with theantenna 580. In various implementations, assembly 120 may communicatewith central controller 140 or with other lighting assemblies 120. Insome cases, assembly 120 may communicate with other electronic devices(e.g., phones, laptops, tablets, police/fire/ambulance communicationsystems, and the like).

The light control module 530 may use various methods in controlling theintensity of the light 540. For example, the light control module 530may use pulse width modulation (PWM) to adjust the power output of anLED type light 540. In some implementations, the average value ofvoltage (and current) fed to the load is controlled by turning theswitch between supply and load on and off at a defined pace. The longerthe switch is on compared to the off periods, the higher the powersupplied to the load may be, for example. An advantage of PWM, in someimplementations, is that power loss in the switching devices may be verylow. When a switch is off there may be practically no current, and whenit is on, there is almost no voltage drop across the switch. Power loss,being the product of voltage and current, may thus in both cases beclose to zero. PWM also works well with digital controls, which, becauseof their on/off nature, can easily set a desired duty cycle.

In some implementations, the light control module 530 includes means forcontrolling current or voltage applied to the light 540, such aspotentiometers, voltage regulators, and other type of current and/orvoltage control. When the light 540 includes an array of luminaries,such as in an LED light, the light control module 530 may selectivelycontrol a portion of the LED arrays to achieve various power outputcontrol. For example, the light may control a portion of sub-lights thatcomprise light 540 to turn on or off. For example, the light controlmodule 530 may enable the same percentage of light arrays on/offaccording to the total power output percentage. In other cases, thecontrol module 530 may cause lights to illuminate at different intensitylevels.

The light control module 530 is connected with the communication module520, the sensor module 510 and a security module 550. The securitymodule 550 may determine the validity of communication between thecommunication module 520 and the light control module 530, byverification techniques such as using pass keys, security answers, andother security techniques. In some embodiments, the security moduleenables the street light assembly 120 or the central controller 140 toreject unauthorized control signals/commands.

The light 540 may be powered by various power sources. A common powersource may be the power supply provided in the city. Optionally, otherrenewable power source such as solar and wind energy may be utilized andstored in local batteries, as well.

The light assembly 120 may include a reference library 570 that includesa variety of sound such as glass shattering, siren, gunshot, screaming,etc. The reference library 570 may be used to compare with the sensedaudio signal to identify the sensed signal. The assembly may adjust itslight output based on the type of sensed signal, for example.

The central controller 140 may include server and control algorithms515, a database 535 and a backup memory 545 (e.g., tape drive). Theserver and control algorithms 515 may include several controlsub-modules such as a light control module 521, a light schedulingmodule 523, a security module 525, a failure notification module 527 andan emergency actions module 529. The database 535 may include historicaldata used to determine the lighting profile, previous sensingmeasurements, and incidental events data. The database 535 may includeall information stored in the local reference library 570 in the streetlight assembly 120, in some implementations.

The light control module 521 may function similarly to the light controlmodule 530, except that it may have higher or lower authority tooverride the local commands. The light control module 521 may usevarious methods in controlling the intensity of the light 540. The lightcontrol module may formulate lighting commands to a particular lightingassembly, for example.

The light scheduling module 523 may be responsible for determining thelighting profile for a lighting assembly or for a group of lightingassemblies. Such profiles can vary on a seasonal, monthly, weekly,daily, or hourly basis, for example, or can vary with respect to eventsor activities. Profiles can vary with seasonal variations. The lightscheduling module 523 may be used to determine the onset and ending ofeach illumination cycle, the rate of change in the profile and otherlighting profile characteristics. As described above, profiles can alsospecify varying levels of information, and the light scheduling module523 can determine an appropriate level of detail for a particularassembly (e.g., based on capability of a particular assembly).

The security module 525 may function similarly as the security module550. The security module 550 may provide a security feature for messagessent from the controller 140, so that the receiving light assembly mayverify that the communication is from a trusted source. In someembodiments, the security module enables the street light assembly 120or the central controller 140 to reject unauthorized controlsignals/commands.

The failure notification module 527 is included to indicate a failure inchanging the lighting profile with sensed signals and/or a failure incommunicating with the street light assembly about the lighting profile.The emergency actions module 529 may allow a user to manually overridethe commands for the street light assembly 120. The override operationincludes manual input of the lighting profile, as well as shutting down,reboot, and/or other operations.

FIG. 6 illustrates an example network system for connecting the lightassembly to the central controller in the street light management systemin accordance with the present disclosure. As described above, in somecases communications that include a security feature may be used to helpcombat against nefarious intent by unauthorized parties. FIG. 6illustrates an example of equipment that can be used to implement aheightened security communications protocol. A commander 650, which maybe the central controller 140 in some implementations or in astreetlight assembly in some implementations, may create acommunications payload that includes a lighting profile or command to beapplied at a lighting assembly, and includes a challenge question andrequired response. The payload is encrypted and signed and sent to thelighting assembly 610 wirelessly via a network (e.g., a microwavenetwork, the Internet, a cellular network, an RF network, or acombination of the foregoing). The lighting assembly 610 receives themessage over an antenna 629 of the lighting assembly. A radio module 627of the lighting assembly delivers the encrypted message to an IPCommunication module 625, where the signal is authenticated and thepayload is decrypted. The decrypted payload is then delivered to aprocessor 623, which parses the payload and optionally delivers thechallenge question to a verification module 621, if provided. Theverification module 621 may interpret the challenge question and replywith an answer to the question. The processor 623 verifies that theresponse from the module 621 matches the response included in themessage, and executes the lighting profile (or begins executing it) ifthe answer is correct. If the answer is incorrect, the command may notbe executed. This may add an extra layer of security of standardencryption/decryption methods, and may add a utility-specific check onsecurity. That is, the entity (e.g., an energy company or city office)in charge of the lighting system may be the only party with access tomodule 621. In some cases, challenge-response security pairs may be onetime use only, and may be time-limited. The module 621 may need toprovide a correct response within a predetermined period of time;otherwise a timeout may prevent further action.

In some implementations, all communications between components of thelighting system may be subject to a security protocol similar to thatdescribed above with reference to FIG. 6. For example, lighting assembly120 (e.g., assembly 120 a, 120 b, . . . 120 i) and/or central controller140 may include one or more aspects of FIG. 6 (e.g., radio 627, module625, processor 623, chip 621) and may decode messages received in themanner described above. Similarly, any of the light assemblies orcontrol centers may be configured to assemble messages that include amessage payload with a challenge question and response. In some cases,encryption and decryption provided by module 625 may be sufficient toalleviate security concerns, but in some cases the extra securityafforded by the challenge question (or security question) and answerfunctionality may be desired. Components that send commands may beconfigured to provide payloads and challenge questions/responses.Components that receive commands or updates may be configured to receiveand process the payloads and challenge questions. In variousimplementations, the communications algorithms used by the variouscomponents may include detection of attempts by unauthorized parties tojam the system, as by a type of cyber-attack, or nuisance disturbancesdesigned to trick the system into providing continuous and uninterruptedlighting at high intensities. In some examples, a single IP address canbe used for communication between components of the system. In someexamples, two IP addresses can be used for communication betweencomponents of the system. In some implementations, secure communicationsmay not be needed, and communications may occur without securityquestions/answers.

In some embodiments, two or more lighting assemblies may collaborate bycontributing signals according to a predetermined weightingdistribution. For example, signals measured at different locations mayhave different significance/priority with respect to activitydetermination. The control system 140 (or one of the lightingassemblies) may use the weighting distribution in determining anappropriate lighting profile or in determining an appropriate deviationfrom the currently assigned lighting profile, according to someimplementations. In some embodiments, some or all of the lightingassemblies may be communicably coupled to the central control system140, and/or may communicate with each other via a mesh network. The meshnetwork may offer fault-tolerant communications among or betweencomponents of the system in certain situations.

The communication scheme may rely primarily on a network such as theinternet, and may also rely on a secondary network such as a cellularnetwork, or a utility channel (e.g. microwave, radio frequency) toestablish direct communication between devices. All communications,end-point authentication, and data-handling may meet any regulatorysecurity requirements, if applicable. In some examples, devices maydirectly connect to the internet or other network, or may indirectlyconnect to the internet or other network via a cellular network, or autility channel, or both.

The control algorithms of the central controller 140 may monitoractivity (type, frequency, level) reported by the lighting assemblies,and may use the information to adjust future lighting profiles so thatenergy can be conserved, lighting pollution can be reduced, or costsavings realized. In some cases, measured activity can be comparedagainst baseline values. In some examples, differential values may becomputed using measurements from two or more lighting assemblies.

In some cases, baseline values can be associated with certain weatherconditions or seasonal conditions. For example, a baseline value mayrepresent a signal expected when particular weather is occurring (rain,hail, snow, wind, calm, or others). In some cases, the system may beaware of the current weather conditions for an area and the algorithmmay use an appropriate baseline value or values when determining alighting profile. As one example, warm ambient temperatures may meanthat more pedestrians are expected than when it is bitterly cold.

Lighting assemblies may use the described sensors to sense for activityat various intervals. For example, in some cases measurements may bedone about once every second, every two seconds, every 3 seconds, every5 seconds, every 10 seconds, every 15 seconds, or according to any otherappropriate measurement interval. In some examples, different sensorsmay monitor at different monitoring intervals.

FIG. 7 shows an example method 700 for managing an energy saving lightsystem in accordance with the present disclosure. The method may also beused to reduce light pollution, for example. The energy managing method700 initiates at step 705, where the street light assembly receives alighting profile. The lighting profile may be prepared by a centralcontroller, for example, and may be received wireless by the lightingassembly following transmission by the central controller. The lightingassembly next implements the lighting profile at step 710, as byilluminating a light at a first intensity specified by the lightingprofile 715. The light assembly may include one or more sensorsconfigured to sense activity. At step 720, the light assembly receivesan input indicating proximate activity. In various examples, theproximate activity may be a passenger walking by, a car driving by,police patrol cars driving by, people gathering, a detectedcommunication signal, a gunshot, the sound of glass shattering, ascream, smoke, natural gas, or chemical particles, and/or network inputfrom collective voting.

The light assembly may next deviate from the lighting profile 725. Inparticular, the lighting assembly may increase (or decrease) thelighting intensity based on the activity detected. At step 730, thestreet light assembly may transmit a message that includes indicationsof increased intensity and an identifier associated with the lightassembly.

FIG. 8 is a schematic diagram of a generic electronic system 800. Thesystem 800 can be used for the operations described in association withany of the computer-implement methods described previously, according tosome implementation. The system 800 includes a processor 810, a memory820, a storage device 830, and an input/output device 840. Each of thecomponents 810, 820, 830, and 840 are interconnected using a system bus850. The processor 810 is capable of processing instructions forexecution within the system 800. In one implementation, the processor810 is a single-threaded processor. In another implementation, theprocessor 810 is a multi-threaded processor. In one implementation, theprocessor 810 is a microcontroller. The processor 810 is capable ofprocessing instructions stored in the memory 820 or on the storagedevice 830 to perform actions associated with the methods discussedherein.

The memory 820 stores information within the system 800. In oneimplementation, the memory 820 is a computer-readable medium. In oneimplementation, the memory 820 is a volatile memory unit. In anotherimplementation, the memory 820 is a non-volatile memory unit.

The storage device 830 is capable of providing mass storage for thesystem 800. In one implementation, the storage device 830 is acomputer-readable medium. In various different implementations, thestorage device 830 may be a floppy disk device, a hard disk device, anoptical disk device, or a tape device.

The input/output devices 840 provides input/output operations for thesystem 800. In some implementation, the input devices include one ormore of the sensors discussed previously. In some implementations, theoutput devices comprise one or more lights of the lighting assembly.

In various implementations, the lighting assemblies may include one ormore portions of the system 800. In various implementations, the centralcontroller may include one or more portions of the system 800. In thecase of the central controller, I/O devices can include keyboard, mouse,display monitor, printer, and the like. The monitor may be used todisplay graphical user interfaces, for example.

The features described can be implemented in digital electroniccircuitry, or in computer hardware, firmware, software, or incombinations of them. The apparatus can be implemented in a computerprogram product tangibly embodied in an information carrier, e.g., in amachine-readable storage device or in a propagated signal, for executionby a programmable processor; and method steps can be performed by aprogrammable processor executing a program of instructions to performfunctions of the described implementations by operating on input dataand generating output. The described features can be implementedadvantageously in one or more computer programs that are executable on aprogrammable system including at least one programmable processorcoupled to receive data and instructions from, and to transmit data andinstructions to, a data storage system, at least one input device, andat least one output device. A computer program is a set of instructionsthat can be used, directly or indirectly, in a computer to perform acertain activity or bring about a certain result. A computer program canbe written in any form of programming language, including compiled orinterpreted languages, and it can be deployed in any form, including asa stand-alone program or as a module, component, subroutine, or otherunit suitable for use in a computing environment.

Suitable processors for the execution of a program of instructionsinclude, by way of example, both general and special purposemicroprocessors, and the sole processor or one of multiple processors ofany kind of computer. Generally, a processor will receive instructionsand data from a read-only memory or a random access memory or both.Storage devices suitable for tangibly embodying computer programinstructions and data include all forms of non-volatile memory,including by way of example semiconductor memory devices, such as EPROM,EEPROM, and flash memory devices; magnetic disks such as internal harddisks and removable disks; magneto-optical disks; and CD-ROM and DVD-ROMdisks. The processor and the memory can be supplemented by, orincorporated in, ASICs (application-specific integrated circuits).

A number of implementations have been described. Nevertheless, it willbe understood that various modifications may be made. Accordingly, otherimplementations are within the scope of the following claims.

1-19. (canceled)
 20. A computer-implemented method of managing energyuse in a system of lights, comprising: receiving, at a communicationsreceiver of a first lighting assembly, a lighting profile that instructsthe first lighting assembly to operate according to the lighting profileover a first period of time, the lighting profile received wirelessly bythe communications receiver from a control center remote from the firstlighting assembly, wherein the control center additionally provideslighting profiles to a plurality of other lighting assemblies;implementing, at the first lighting assembly, the received lightingprofile, including causing a light of the first lighting assembly toilluminate at a first intensity; receiving, at a sensing module of thefirst lighting assembly, an input acquired in proximity to the firstlighting assembly, the input indicating an activity level in a regionproximate the first lighting assembly; deviating from the receivedlighting profile by varying the intensity of the light of the firstlighting assembly, in response to the received input acquired inproximity to the first lighting assembly, by causing the light of thefirst lighting assembly to illuminate at a second intensity for apredetermined period of time, the second intensity different than thefirst intensity; and wirelessly transmitting a message via acommunications transmitter of the first lighting assembly for receipt bythe control center, the message comprising an indication of the secondintensity and an identifier associated with the first lighting assembly.21. The computer-implemented method of claim 20, wherein the secondintensity is greater than the first intensity.
 22. Thecomputer-implemented method of claim 20, wherein the second intensity isless than the first intensity.
 23. The computer-implemented method ofclaim 20, wherein the input comprises a radio frequency signalindicative of an electronic device used within the region proximate thefirst lighting assembly.
 24. The computer-implemented method of claim23, wherein the input comprises request for additional light and isassociated with a particular electronic device or user, and furthercomprising increasing the intensity of the light and billing theparticular electronic device or user for the request.
 25. Thecomputer-implemented method of claim 23, wherein the radio frequencysignal is received from an emergency response communication system. 26.The computer-implemented method of claim 20, wherein the input comprisesa sound.
 27. The computer-implemented method of claim 26, wherein in thesound is a gunshot sound.
 28. The computer-implemented method of claim26, wherein the sound is associated with a motorized vehicle.
 29. Thecomputer-implemented method of claim 20, wherein the input comprises alight signal based on ambient lighting conditions.
 30. Thecomputer-implemented method of claim 20, wherein the input comprisesdetected motion within the region proximate the first lighting assembly.31. The computer-implemented method of claim 20, wherein the lightingprofile is based on expected weather conditions.
 32. Thecomputer-implemented method of claim 20, wherein communications betweenthe first lighting assembly, the control center, and the plurality ofother lighting assemblies occur over a mesh network.
 33. Thecomputer-implemented method of claim 20, wherein the sensing modulecomprises a long-range motion sensor.
 34. The computer-implementedmethod of claim 20, further comprising receiving, at the communicationsreceiver of the first lighting assembly, a communication from a secondlighting assembly, and varying light intensity of the light of the firstlighting assembly based on the received communication from the secondlighting assembly.
 35. The computer-implemented method of claim 20,wherein the message includes an indication of energy usage by the firstlighting assembly.
 36. The computer-implemented method of claim 35,wherein the control center, based on the indication of energy usage andon other indications of energy usage received from other lightingassemblies of the plurality of other lighting assemblies, determines asecond lighting profile and instructs one or more lighting assemblies toimplement the second lighting profile.
 37. The computer-implementedmethod of claim 20, wherein the message includes a request that thecontrol center instruct lighting assemblies in a vicinity of the firstlighting assembly to adjust their light intensities.
 38. Thecomputer-implemented method of claim 20, further comprising wirelesslytransmitting a second message via the communications transmitter of thefirst lighting assembly for receipt by other lighting assemblies of theplurality of other lighting assemblies, the second message comprising aninstruction to the other lighting assemblies to adjust their lightintensities.
 39. The computer-implemented method of claim 20, furthercomprising receiving, with the lighting profile, a security question,the lighting profile and the security question included in a messagefrom the control center, and wherein accessing the lighting profile isdependent on the first lighting assembly providing a correct answer tothe security question.
 40. The computer-implemented method of claim 20,wherein the message includes an indication of the input acquired inproximity to the first lighting assembly, and wherein the controlcenter, based on the indication of the input and on other indications ofinputs received from other lighting assemblies of the plurality of otherlighting assemblies, determines a second lighting profile and instructsone or more lighting assemblies to implement the second lightingprofile.
 41. A lighting assembly, comprising: a light; a communicationsreceiver configured to receive a lighting profile that instructs thelighting assembly to operate according to the lighting profile over afirst period of time, the lighting profile received wirelessly by thecommunications receiver from a control center remote from the lightingassembly, wherein the control center additionally provides lightingprofiles to a plurality of other lighting assemblies; a light controlmodule configured to implement the received lighting profile, includingcausing the light to illuminate at a first intensity; a sensor moduleconfigured to receive an input acquired in proximity to the lightingassembly, the input indicating an activity level in a region proximatethe lighting assembly; wherein the light control module is additionallyconfigured to deviate from the received lighting profile by varying theintensity of the light, in response to the received input acquired inproximity to the lighting assembly, by causing the light to illuminateat a second intensity for a predetermined period of time, the secondintensity different than the first intensity; and a communicationstransmitter configured to wirelessly transmit a message, for receipt bythe control center, the message comprising an indication of the secondlight intensity and an identifier associated with the lighting assembly.